Ross (née, CAESAR) Presentation to SBAG Beau Bierhaus, Ben Clark, Josh Hopkins 18 January 2018
First, A Word on Names Our proposal was named Cubesat Asteroid Encounters for Science And Reconnaissance (CAESAR) This overlaps with the name of a recently selected New Frontiers Phase A study for a different small bodies mission To avoid confusion, we are changing the mission name to Ross Mary G. Ross was an engineer at Lockheed Martin from 1942-1973, and one of the first American Indians in aerospace engineering Her worked spanned WW II to the space age, including interplanetary trajectory analysis We honor her groundbreaking role and contributions to orbital mechanics with this mission 2
Some Planetary Science Deep Space Smallsat Studies (PSDS3) Mission Concept Parameters Any Solar System body, including NEOs (excluding the Sun & Earth). Multiple targets are permitted. Secondary payload No Radioisotope power systems or heater units 3
Ross Mission Overview Study objective Demonstrate that a fleet of small, low-cost spacecraft provides an affordable means to explore an incredibly diverse smallbody population via flybys Why flybys? A well-planned and executed flyby on a new object provides a wealth of information on: Shape and size (and thus volume), spin rate, pole orientation, thermal processes, dominant surface features and properties Flybys provide an excellent balance between a necessary data set, accessing a large number of objects, AND the feasibility of implementing the mission via a small-scale spacecraft 4
Why the smallest NEOs? Despite their diminutive size, there are fundamental physical processes present in small asteroids, including: The balance of forces (gravity, rotation, cohesion), which can be related back to planetary formation Collisional evolution, which is relevant to all small body populations Response to thermal flux & orbit evolution Existing observations of small bodies demonstrate that the geology of these objects include shape and structure more complex than previously expected Bennu, from Nolan et al. (2013) Itokawa, from Michikami et al. (2010) 5
By the Numbers Most objects in the solar system belong to a physical scale that has never been visited by spacecraft Small objects are... The vast majority of planetary bodies The greatest remaining unknown risk for Earth impact Candidate targets for ISRU and / or human exploration Number per size bin 6
Small Bodies are Fundamentally Multiple New Regimes The relative magnitudes of gravity, cohesion, and centripetal acceleration are wholly different than other planetary objects (Scheeres et al. 2010) The role of gravity relative to cohesion and centripetal acceleration is different between asteroid scales i.e. a 1 km object and a 5 km object are different creatures The balance of forces has relevance to planetary formation, i.e. the progressive accretion of material into larger aggregates Scheeres et al. (2010) 7
Thermal Effects Yarkovsky effect peaks at diameters < a few km Small asteroids provide an excellent laboratory to measure the Yarkovsky effect, and to understand cause-and-effect between measured value and resolved, specific physical characteristics YORP effects on rotation rate and obliquity scale as 1/R 2 (R = asteroid radius) The smaller the asteroid, the bigger the YORP effect Bottke et al. (2002). The change in orbital semi-major axis, due to Yarkovsky, as a function of object size. Different curves are different surface conductivities. Small objects are an excellent population to explore cause and effect for thermal properties and orbital evolution! 8
Flybys Provide Valuable Reconnaissance A simple flyby with a low-cost spacecraft can significantly reduce the programmatic cost and risk of a subsequent mission For example, diameter uncertainties from ground-based observations correspond to much larger uncertainties in object mass A small, inexpensive flyby is an effective scouting to constrain the parameter space for a larger, follow-on mission The combined cost of a (cubesat flyby) + (large follow-on mission) could be less than a large mission that has to design for a much larger parameter space 9
Ross Mission Description Multiple cubesats launched as secondary payloads Option space: 1. Each cubesat targets a different NEO 2. Multiple cubesats target a single NEO to improve coverage of highvalue target 3. Some combination of 1 and 2 Initial target search identified dozens of possible candidates Ongoing evaluation of target viability includes low ΔV, low flyby velocities, favorable approach phase angles and other constraints Candidates include a comet, a range of spectral types, and many untyped objects Search for additional candidate targets continues 10
Ross Mission Architecture Several identical spacecraft perform flybys of previously unexplored NEOs Two science instruments: Visible camera IR camera, focusing on measuring thermal inertia and temperatures X-band telecom Propulsion for tailoring of trajectory Leverages Lockheed Martin investment in CubeSat technology, including LunIR on EM-1 Science Team Beau Bierhaus, Ben Clark, Lockheed Martin Robert Jedicke, University of Hawaii Mike Ravine, Malin Space Science Systems Driss Takir, SETI Institute If you are interested in this concept, please let me know 11
Summary Small asteroids and comets are not just compositional remnants of the early solar system, they are living examples of physical processes that occurred in the early solar system Yarkovsky and YORP have always been around the physical processes of regolith creation, retention, and loss are relevant to early accretion Small objects are part of the greatest uncategorized impact risk, and are good candidates for future exploration There are more than 15,000 known Near-Earth Objects, with orders of magnitude more to be discovered, making it impossible for Discovery-class missions to explore more than a tiny fraction of them we need a new paradigm (SIMPLEX)! 2018 Lockheed Martin Corporation. All Rights Reserved. 12
References Bottke et al. (2002). The Effect of Yarkovsky Thermal Forces on the Dynamical Evolution of Asteroids and Meteoroids. In Asteroids III, Bottke, Cellino, Paolicchi, Binzel, eds. Univ of AZ Press. Michikami et al. (2010). The shape distribution of boulders on Asteroid 25143 Itokawa: Comparison with fragments from impact experiments. Icarus, v. 207, pp. 277-284. Nolan et al. (2013). Shape model and surface properties of the OSIRIS-REx target Asteroid (101955) Bennu from radar and lightcurve observations. Icarus, v. 226, pp. 629-640. Scheeres et al. (2010). Scaling forces to asteroid surfaces: The role of cohesion. Icarus, v. 210, pp. 968-984. 13